The present disclosure discloses a Single-Event Transient (SET) pulse measuring circuit capable of eliminating impact thereof, and an integrated circuit chip. The SET pulse measuring circuit capable of eliminating impact thereof includes four parts: a SET pulse test chain, a latch circuit, a flip-flop test circuit, a latching self-trigger circuit. The integrated circuit chip is provided with a test chain module and two sets of SET pulse measuring circuits capable of eliminating impact thereof, and inputs of the two sets of SET pulse measuring circuits capable of eliminating impact thereof are the same and each are connected to an output terminal of the test chain module.

The present invention provides a glitch detector including a first inverter, a second inverter, a first capacitor and a second capacitor. The first inverter is connected between a supply voltage and a ground voltage, and is configured to receive a first signal at a first node to generate a second signal to a second node. The second inverter is connected between the supply voltage and the ground voltage, and is configured to receive the second signal at the second node to generate the first signal to the first node. A first electrode of the first capacitor is coupled to the supply voltage, and a second electrode of the first capacitor is coupled to the first node. A first electrode of the second capacitor is coupled to the ground voltage, and a second electrode of the second capacitor is coupled to the second node.

The signal toggling detection and correction circuit includes a flip-flop, a checker circuit, and a fault monitoring circuit that includes a restoration circuit. Based on faults such as soft errors and unintended bit toggles in the flip-flop, a flop output signal toggles. A set of checker signals outputted by the checker circuit may toggle based on toggling of the flop output signal and a restoration signal of the restoration circuit. Based on the toggling of at least one checker signal, the fault monitoring circuit determines whether the flip-flop or the checker circuit is faulty. When the checker circuit is faulty, the fault monitoring circuit corrects the toggling of at least one checker signal. When the flip-flop is faulty, the fault monitoring circuit corrects the toggling of one of the toggled flop output signal or the restoration signal and further corrects the toggled checker signal.

An integrated circuit for hardware security comprises a voltage glitch detection processing system comprising an oscillator circuit that generates and outputs a local oscillator clock which is a function of a supply voltage; a counter clocked by the oscillator circuit to generate at least one count value; and a capture section that synchronizes the at least one count value into a system clock domain for detecting a voltage glitch in the supply voltage.

The signal toggling detection and correction circuit includes a flip-flop, a checker circuit, and a fault monitoring circuit that includes a restoration circuit. Based on faults such as soft errors and unintended bit toggles in the flip-flop, a flop output signal toggles. A set of checker signals outputted by the checker circuit may toggle based on toggling of the flop output signal and a restoration signal of the restoration circuit. Based on the toggling of at least one checker signal, the fault monitoring circuit determines whether the flip-flop or the checker circuit is faulty. When the checker circuit is faulty, the fault monitoring circuit corrects the toggling of at least one checker signal. When the flip-flop is faulty, the fault monitoring circuit corrects the toggling of one of the toggled flop output signal or the restoration signal and further corrects the toggled checker signal.

A system and method to manage a single event latched (SEL) condition, the method including operations to monitor, for a predetermined condition associated with single event latched (SEL) states, a reset signal output from a watchdog device to a microprocessor, wherein the reset signal is responsive to a malfunction condition associated with the microprocessor. The method further includes operations to control provision of power to the microprocessor in response to detection of the predetermined condition.

Disclosed herein is a test circuit for a 3D semiconductor device for detecting soft errors and a method for testing thereof. The test circuit includes a first Multiple Input Signature Register (MISR) disposed in a first semiconductor chip, the first MISR compressing a first test result signal corresponding to a test pattern, a second MISR disposed in a second semiconductor chip stacked on or under the first semiconductor chip, the second MISR compressing a second test result signal corresponding to the test pattern, and a first error detector to detect a soft error by comparing a first output signal output from the first MISR with a second output signal output from the second MISR.

Described herein is a method implemented by circuitry for providing fault tolerance in a combinational circuit. The circuitry identifies sensitive gates of the circuit that require protection from at least one of a first type of fault and a second type of fault. Further, circuitry computes for each first type of transistor included in the sensitive gate, a first failure probability, and for each second type of transistor included in the sensitive gate, a second failure probability. The circuitry calculates a first parameter corresponding to a number of the first type of transistors for which the computed first failure probabilities exceed a first predetermined threshold and a second parameter corresponding to a number of second type of transistors for which the computed second failure probabilities exceed a second predetermined threshold to determine a protection type based on an area overhead constraint.

Systems and methods for latch-up detection and mitigation. One aspect includes a method implemented in a system divided into a plurality of power blocks, where each power block is powered by a corresponding power rail and includes a voltage droop monitoring circuitry. The method comprises receiving frequency information from the plurality of voltage droop monitoring circuitries; normalizing the received frequency information from each of the plurality of voltage droop monitoring circuitries; creating a matrix of cross-correlation values based on the normalized frequency information between each pair of the plurality of power blocks; determining deviations in the cross-correlation values indicating an occurrence of voltage droop; determining an abnormal variation based on the determined deviations to identify a first power block, out of the plurality of power blocks, experiencing a latch-up event; and resetting power to the first power block without interrupting power to rest of the plurality of power blocks.

An integrated circuit for hardware security comprises a voltage glitch detection processing system comprising an oscillator circuit that generates and outputs a local oscillator clock which is a function of a supply voltage; a counter clocked by the oscillator circuit to generate at least one count value; and a capture section that synchronizes the at least one count value into a system clock domain for detecting a voltage glitch in the supply voltage.